DE9321018U1 - Device for ventilation of rooms - Google Patents

Description

Device for ventilating rooms

The invention relates to a device for ventilating rooms according to the preamble of claim 1.

Devices of this type are used in particular for ventilating rooms, with the fan moving the air from the room outside or into an exhaust air system. Devices of this type are used in particular for ventilating interior rooms without external windows, e.g. bathrooms and toilets or kitchens or storage rooms. Of course, such devices can also be used to supply fresh air into rooms. The ventilation ensures clean air and a healthy indoor climate in the rooms. In interior rooms without windows, the ventilation also serves in particular to remove odors, moisture and pollutants.

As a rule, a filter is arranged on the intake side in front of the fan of the device, in most applications in

Postgiroamt: Karlsruhe 769 79-754 Bank account: Deutsche Banx AQ Viüingen (bank code 694700 39) 146 332

Form of a large-area filter mat. When ventilating, the filter prevents dust and dirt from being fed into the exhaust air system via the device and settling in this exhaust air system, which is difficult to access for cleaning, whereby the function of non-return valves and fire protection flaps may be impaired. When air is supplied, the filter prevents dust and dirt from being fed into the rooms from outside.

In order for the device to be able to adequately fulfill its ventilation function, it must be designed for the corresponding volume flows. For example, the German standard DIN 18017 T3 provides the corresponding dimensioning regulations for the ventilation of bathrooms and toilet rooms without external windows. However, the device only conveys the volume flows corresponding to its dimensions if the filter has sufficient air permeability. The air permeability of the filter decreases as it becomes increasingly dirty, so that the device can no longer convey the intended volume flows despite being appropriately dimensioned. The filter must therefore be changed when it reaches a certain level of dirt so that the device remains functional. Since the filter is usually covered by a screen, the level of dirt cannot be seen, so that the reduction in air permeability is also not noticed. The device is therefore often operated for long periods with a dirty filter and does not fulfill its function. This can lead to disruptions to the health and well-being of the residents and to damage to the building structure if the moisture is not removed properly.

The invention is therefore based on the object of providing a device for ventilating rooms, which

the risk of operation with insufficient air supply is reduced.

This object is achieved according to the invention with a device having the features of claim 1.

Advantageous embodiments of the invention are specified in the subclaims.

According to the invention, a possibility is created to continuously monitor the functionality of the device during operation. For this purpose, the air flow through the filter is determined. A display shows the air flow through the filter so that the filter can be replaced as soon as the required air flow is no longer guaranteed. In general, it is not necessary to know the air flow through the filter exactly; it is sufficient if the drop in the air flow below a minimum value is displayed, which makes it necessary to replace the filter.

To determine the air flow through the filter, all known methods can be used.

For example, the negative pressure behind the filter can be determined. This negative pressure caused by the suction effect of the fan increases when the air flow through the filter decreases due to contamination, since sufficient pressure equalization cannot be achieved by the air flowing through the filter. The pressure difference between the front and back of the filter can also be determined. This pressure difference also increases when the pressure equalization through the filter decreases due to contamination.

is hindered.

It is also possible to determine the air flow rate using the flow rate of the air flowing through the filter. Mechanical effects can be used for this purpose, e.g. by rotating blades with tangential or axial impact from the flowing air or by so-called wind vane switches. Thermal effects can also be used, e.g. by a thermoelectric probe, such as the so-called hot wire probe.

Measuring the pressure or differential pressure is relatively complex. Measuring the flow rate of the air flowing through the filter is relatively sensitive, since the flow rate is low due to the usually large-area filters.

In an advantageous embodiment, a bypass channel is therefore arranged parallel to the filter in the flow path of the fan. The flow resistance of this bypass channel is significantly greater than the flow resistance of the large-area filter, as long as its air permeability is not impaired by contamination. As long as the filter is functional, the air sucked in by the fan flows through the filter and not through the bypass channel. If the air permeability of the filter decreases as a result of contamination, the pressure difference between the front and back of the filter and thus between the front and back of the bypass channel increases. As the degree of contamination of the filter increases, an increasingly increasing air volume flow flows through the bypass channel. The air flow through the bypass channel is therefore a measure of the degree of contamination of the filter. The air flow through the bypass channel changes as a result.

strong, so that a simple determination is possible. In particular, the change in the flow rate of the air in the bypass channel can be easily determined with sufficient accuracy for the contamination indication. Here too, a thermoelectric effect can be used, for example by arranging a hot wire probe in the bypass channel. The above-mentioned mechanical effects can also be used effectively to determine the flow rate in the bypass channel.

The air flow can also be displayed in different ways. Since the display should use as little energy as possible and since a longer period of time may pass before the filter is replaced, a visual display is preferable to an acoustic display.

An electrical light display can be used as an optical display, for example. A mechanically movable display element can also be used, which is independent of a power supply and has a longer service life.

In many known measuring methods it is necessary to convert the mechanical measurement variable into an electrical variable or the measurement variable is available as an electrical variable, as in the case of thermoelectric measuring methods. In such cases either an electrical display is required or a further conversion of the electrical variable into a mechanical display is required. In order to avoid the effort associated with such mechanical-electrical or electro-mechanical converters, a mechanical measurement of the air flow and a mechanical display element that are mechanically coupled are preferably used.

This makes it possible to implement functional monitoring using simple mechanical means that have only a negligible impact on the overall cost of the device.

In an extremely simple and inexpensive design, the air flow through the filter is therefore determined by the flow speed in a bypass channel, whereby a float in the bypass channel is carried along by the air flowing through it against a restoring force. The display element can be attached directly to the float, whereby its position corresponding to the movement of the float forms the optical display. In the simplest case, the restoring force acting on the float can be generated by the float's own weight if the bypass channel is arranged vertically and the air flows through it from bottom to top. If such an arrangement of the bypass channel is not possible for structural reasons or because of the installation position of the device, the restoring force can be generated by a spring acting on the float.

The invention is explained in more detail below using an embodiment shown in the drawing. Show

Figure 1 shows a vertical axial section through a

Device for ventilating rooms,

Figure 2 a front view of the device with

removed aperture,

Figure 3a and b a top view of the monitoring device with the cap removed and the filter functioning (Figure 3a) and

with dirty filter (Figure 3b),

Figure 4a and b a plan view corresponding to Figure 3 of

the monitoring device with the cap in place when the filter is functioning (Figure 4a) and when the filter is dirty (Figure 4b) and

Figure 5a and b show a vertical section through the monitoring device with a functioning filter (Figure 5a) and with a dirty filter (Figure 5b).

The device for ventilating rooms has a housing 10 which is installed in the wall of the room. A fan is installed in the housing 10, which consists of a radial fan wheel 14 driven by an electric motor 12. An inlet nozzle 16 leads axially from an intake-side chamber 18 of the housing to the radial fan wheel 14. The exhaust-side chamber 20 of the housing 10 is connected to an exhaust air system of the building in a manner not shown.

On the intake side in front of the fan, the intake side chamber 18 of the housing 10 is closed off by a frame 22. The frame 22 is sealed by a seal 24 on the room-side edge of the housing 10. The frame 22 has a large opening in the middle with a grille 26. A filter 28 designed as a filter mat is inserted into this opening, which is supported by the grille 26.

A cover 30 is arranged on the room side in front of the frame 22 with the filter 28. The cover 30 covers the frame 22 and the filter 28. The cover 30 is separated from the frame 22 and

the filter 28 so that a gap remains between the frame 22 and the panel 30, through which air can be sucked in from the room, which passes through the filter 28 and is conveyed into the exhaust air system via the fan.

To monitor the functionality of the device, i.e. the air permeability of the filter 28, a bypass channel 32 is provided on the frame 22 below the filter 28. The bypass channel 32 shown in detail in Figures 3 to 5 has a U-profile 34 integrally formed on the plastic frame 22. The U-profile 34 is aligned vertically, with the profile base being formed by the frame 22 and the profile legs projecting vertically from the frame 22. At the upper end of the U-profile 34, a hole 36 is provided in the profile base, which leads through the frame 22 to the intake chamber 18 of the fan. At the lower end of the U-profile, its legs narrow to form a vertical guide slot 38 that is centrally connected to the U-profile 34. A plastic cap 40 is placed on the U-profile, which is open at the front. The cap 40 has the shape of a rectangular cuboid that is open on the side facing the frame 22. The cap 40 sits snugly on the U-profile 34 and seals it tightly on its open front side facing away from the frame 22. The cap 40 also encloses the guide slot 38. In the front surface parallel to the frame 22, the cap 40 has an opening 42 in its lower area. The opening 42 has the shape of a vertical, elongated slot, the upper end of which extends beyond the lower end of the U-profile 34. In its middle area above the guide slot 38, the opening 42 is widened to form a viewing window 44. Through the opening 42, the U-profile 34 and the

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The bypass channel 32 is thus formed in the bore 36, which allows air to pass from the room side parallel to the filter 28 to the intake side of the fan.

A floating body 46 is arranged in the vertical bypass channel 32. The floating body 46 is made in one piece from plastic and has a thin vertical rod, at the upper end of which a wing 48 is formed. The wing 48 sits transversely in the U-profile 34 and closes it off except for a passage gap on both sides. At the lower end, the floating body 46 has a guide nose 50 that engages in the guide slot 38 and is guided in a sliding manner in it. Furthermore, a signaling surface 52 is formed on the lower end of the floating body 46, which is formed in the area of the guide nose 50, runs perpendicular to it and rests on the legs of the guide slot 38 so that it is guided between the legs of the guide slot 38 and the front surface of the cap 40. The signaling surface 52 has a red signal color, for example.

The functionality of the monitoring device is explained using Figures 3 to 5.

The running fan sucks air out of the intake chamber 18 and conveys it through the exhaust-side chamber 20 into the exhaust air system. This creates a negative pressure in the intake chamber 18, through which air is sucked in from the room. The large-area filter 28 has a much larger air passage cross-section than the bypass channel 32. The room air is thus sucked in through the filter 28, so that only a small pressure difference is built up between the room and the intake chamber 18. As long as only this small

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If there is a pressure difference, only a minimal amount of air flows through the bypass channel 32. The float 46 is therefore held by its own weight in the lower stop position shown in Figures 3a, 4a and 5a. In this lower position, the reporting surface 22 is located below the viewing window 44, so that only the narrow rod of the float is visible in it.

If the filter 28 becomes clogged with increasing contamination, its air permeability is increasingly reduced. As the contamination increases, an insufficient volume of air from the room cannot flow through the filter 28 into the intake chamber 18. This creates an increasingly large pressure difference between the room and the intake chamber 18. Due to this large pressure difference, a larger air volume flow now flows at a high flow rate through the bypass channel 32. Since the cross section of the U-profile 34 is largely closed off by the wing 48 of the floating body 46, the air flow carries the floating body 46 upwards against its own weight. Since the air flow flows symmetrically around the wing 48 on both sides and the weight of the floating body acts on the wing 48 at the bottom, the floating body 46 is in a stable position in the air flow, whereby the wing 48 does not come into contact with the side walls of the U-profile 34. The floating body 46 moves in this way in the bypass channel without being able to tilt or jam. The floating body 46 is carried upwards by the air flow until it hits an edge 54 of the profile legs with the reporting surface 52 in the end position shown in Figures 3b, 4b and 5b. In this end position, the reporting surface 52 of the floating body 46 is behind the viewing window 44 of the cap 40 and can be seen from the room via a

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visible through the viewing window 56 of the panel 30. The appearance of the signaling surface 52 in the viewing window 56 indicates to the people in the room that the air flow through the filter 28 is no longer sufficient and that the filter 28 must be replaced.

Claims (17)

1. Device for ventilating rooms, with a fan and with a filter associated with the fan, characterized in that the air flow through the filter (28) is determined to monitor the functionality and at least the drop in the air flow below a minimum value is displayed. 2. Device according to claim 1, characterized in that to determine the air flow through the filter (28) the pressure behind the filter (28) or the difference between the pressures in front of the filter (28) and behind the filter (28) is determined. 3. Device according to claim 1, characterized in that to determine the air flow through the filter (28) the flow velocity of the air flowing through the filter (28) is determined. 4. Device according to claim 1, characterized in that a bypass channel (32) is arranged parallel to the filter (28) in the flow path of the fan (12, 14), the flow resistance of which is significantly greater than the flow Postgiroamt: Karlsruhe 769 79-*754**Bank account:*Deutsche*Birlk AG VUlingen (bank code 69470039) 146 332 resistance of the uncontaminated filter (28), and that the air flow through the bypass channel (32) is determined to determine the air flow through the filter (28). 5. Device according to claim 4, characterized in that to determine the air flow through the bypass channel (32) the flow velocity in the bypass channel (32) is determined. 6. Device according to one of claims 3 to 5, characterized in that the air flow is determined by a thermoelectric probe. 7. Device according to one of claims 3 to 5, characterized in that the air flow is determined by means of at least one body mechanically acted upon by the air flow. 8. Device according to one of the preceding claims, characterized in that the air flow is displayed optically. 9. Device according to claim 8, characterized in that the optical display has a mechanically movable display element. 10. Device according to claims 7 and 9, characterized in net that the at least one body and the display element are mechanically coupled. 11. Device according to claims 5 and 7, characterized in that a floating body (46) is arranged in the bypass channel (32), which can be moved by the air flow against a restoring force. 12. Device according to claims 10 and 11, characterized in that the display element (52) is arranged on the floating body (46). 13. Device according to claim 12, characterized in that the display element has a reporting surface (52) which can be moved in front of a viewing window (44) and away from the viewing window (44) by the movement of the floating body (46). 14. Device according to claim 11, characterized in that the floating body (46) has a wing (48) positioned transversely to the air flow. 15. Device according to one of claims 11 to 14, characterized in that the bypass channel (32) is arranged vertically and the restoring force is the dead weight of the floating body (46). 16. Device according to one of claims 11 to 15, characterized in that the bypass channel (32) is a The frame (22) of the filter (28) has a U-profile (34) formed thereon, which receives the floating body (46), is closed off by a cap (40) and the U-profile (34) is connected at one end to one flow side of the filter (28) via a bore (36) leading through the frame (22) and at the other end to the other flow side of the filter (28) via an opening (42) in the cap (40). 17. Device according to claims 13 and 16, characterized in that the opening (42) of the cap (40) forms the viewing window (44).